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Example: [ Z m ;+,*] is a field iff m is a prime number [a] -1 =?

Example: [ Z m ;+,*] is a field iff m is a prime number [a] -1 =? If GCD(a,n)=1,then there exist k and s, s.t. ak+ns=1, where k, s Z. ns=1-ak. [1]=[ak]=[a][k] [k]= [a] -1 Euclidean algorithm.

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Example: [ Z m ;+,*] is a field iff m is a prime number [a] -1 =?

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  1. Example: [Zm;+,*] is a field iff m is a prime number • [a]-1=? • If GCD(a,n)=1,then there exist k and s, s.t. ak+ns=1, where k, sZ. • ns=1-ak. • [1]=[ak]=[a][k] • [k]= [a]-1 • Euclidean algorithm

  2. Theorem 6.31(Fermat’s Little Theorem): if p is prime number, and GCD(a,p)=1, then ap-11 mod p • Corollary 6.3: If p is prime number, aZ, then apa mod p

  3. Definition 27: The characteristic of a ring R with 1 is the smallest nonzero number n such that 0 =1 + 1 + · · · + 1 (n times) if such an n exists; otherwise the characteristic is defined to be 0. We denoted by char(R). • Theorem 6.32: Let p be the characteristic of a ring R with e. Then following results hold. • (1)For aR, pa=0. And if R is an integral domain, then p is the smallest positive number such that 0=la, where a0. • (2)If R is an integral domain, then the characteristic is either 0 or a prime number.

  4. 6.6.3 Ring homomorphism • Definition 28: A function  : R→S between two rings is a homomorphism if for all a, bR, • (1)  (a + b) = (a) + (b), • (2)  (ab) =  (a)  (b) • An isomorphism is a bijective homomorphism. Two rings are isomorphic if there is an isomorphism between them. • If : R→S is a ring homomorphism, then formula (1) implies • that  is a group homomorphism between the groups [R; +] and [S; +’ ]. • Hence it follows that • (a) (0R) =0S and  (-a) = - (a) for all aR. • where 0R and 0S denote the zero elements in R and S;

  5. If : R→S is a ring homomorphism,  (1R) = 1S? No Theorem 6.33: Let R be an integral domain, and char(R)=p. The function :RR is given by (a)=ap for all aR. Then  is a homomorphism from R to R, and it is also one-to-one.

  6. 6.6.4 Subring, Ideal and Quotient ring 1. Subring Definition 29: A subring of a ring R is a nonempty subset S of R which is also a ring under the same operations. Example :

  7. Theorem 6.34: A subset S of a ring R is a subring if and only if for a, bS: • (1)a+bS • (2)-aS • (3)a·bS

  8. Example: Let [R;+,·] be a ring. Then C={x|xR, and a·x=x·a for all aR} is a subring of R. Proof: For x,yC, x+y,-x?C, x·y?C i.e. aR,a·(x+y)=?(x+y)·a,a·(-x)=?(-x)·a,a·(x·y) =?(x·y)·a

  9. 2.Ideal(理想) • Definition 30:. Let [R; + , * ] be a ring. A subring S of R is called an ideal of R if rs S and srS for any rR and sS. • To show that S is an ideal of R it is sufficient to check that • (a) [S; +] is a subgroup of [R; + ]; • (b) if rR and sS, then rsS and srS.

  10. Example: [R;+,*] is a commutative ring with identity element. For aR,(a)={a*r|rR},then [(a);+,*] is an ideal of [R;+,*]. • If [R;+,*] is a commutative ring, For aR, (a)={a*r+na|rR,nZ}, then [(a);+,*] is an ideal of [R;+,*].

  11. Principle ideas • Definition 31: If R is a commutative ring and aR, then (a) ={a*r+na|rR} is the principle ideal defined generated by a. • Example: Every ideal in [Z;+,*] is a principle. • Proof: Let D be an ideal of Z. • If D={0}, then it holds. • Suppose that D{0}. • Let b=minaD{|a| | a0,where a D}.

  12. 3. Quotient ring Theorem 6.35: Let [R; + ,*] be a ring and let S be an ideal of R. If R/S ={S+a|aR} and the operations  and  on the cosets are defined by (S+a)(S+b)=S+(a + b) ; (S+a)(S+b) =S+(a*b); then [R/S;  ,  ] is a ring. Proof: Because [S;+] is a normal subgroup of [R;+], [R/S;] is a group. Because [R;+] is a commutative group, [R/S;] is also a commutative group. Need prove [R/S;] is an algebraic system, a sumigroup, distributive laws

  13. Definition 32: Under the conditions of Theorem 6.35, [R/S;  , ] is a ring which is called a quotient ring.

  14. Definition 33: Let  be a ring homomorphism from ring [R;+,*] to ring [S;+’,*’]. The kernel of  is the set ker={xR|(x)=0S}. • Theorem 6.36: Let  be a ring homomorphism from ring [R;+,*] to ring [S;+’,*’]. Then • (1)[(R);+’,*’] is a subring of [S;+’,*’] • (2)[ker;+,*] is an ideal of [R;+,*].

  15. Theorem 6.37(fundamental theorem of homomorphism for rings): Let  be a ring homomorphism from ring [R;+,*] to ring [S;+’,*’]. Then • [R/ker;,] [(R);+’,*’]

  16. Exercise: • 1. Determine whether the function : Z→Z given by f(n) =2n is a ring homomorphism. • 2. Let f : R→S be a ring homomorphism, with A a subring of R. Show that f(A) is a subring of S. • 3. Let f: R→S be a ring homomorphism, with A an ideal of R. Does it follow that f(A) is an ideal of S? • 4.Prove Theorem 6.36

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